Method and system for signing an artificial intelligence watermark using a kernel

ABSTRACT

In one embodiment, a computer implemented method of a data processing (DP) accelerator providing a watermark of an artificial intelligence (AI) model to a host device includes receiving, by the DP accelerator, from the host device, the AI model, and a watermark-enabled kernel to the DP accelerator. The DP accelerator further receives from the host device, first input data to the DP accelerator that, when the first input data is used as input to the watermark-enabled kernel, generates a watermark of the AI model. The watermark is provided to the host device. In an embodiment, the method further includes receiving a signature kernel from the host device and calling the signature kernel to digitally sign the watermark. In an embodiment, the method alternatively includes calling a digital signature routine in a secure unit of the DP accelerator to digitally sign the watermark.

TECHNICAL FIELD

Embodiments of the present disclosure relate generally to artificialintelligence model training and inference. More particularly,embodiments of the disclosure relate to artificial intelligence modeltraining and inference and the associated security performed by dataprocessing accelerators.

BACKGROUND

Artificial intelligence (AI) models (also termed, “machine learningmodels”) have been widely utilized recently as AI technology has beendeployed in a variety of fields such as image classification orautonomous driving. Similar to an executable image or binary image of asoftware application, an AI model, when trained, can perform aninference based on a set of attributes to classify as features. As aresult, an AI model can be “portable” and utilized withoutauthorization. Currently there has been a lack of effective digitalrights protection for AI models. In addition, a processing task using anAI model delegated to a secondary processing system, such as aprocessing (DP) accelerator or remote system, there has been lack ofproof that the results produced by the DP accelerator system areprotected by a “root of trust” system.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the disclosure are illustrated by way of example and notlimitation in the figures of the accompanying drawings in which likereferences indicate similar elements.

FIG. 1 is a block diagram illustrating a secure processing system,according to one embodiment.

FIGS. 2A and 2B are a block diagrams illustrating a secure computingenvironment between one or more hosts and one or more data processingaccelerators, according to one embodiment.

FIGS. 3A and 3B are block diagrams illustrating a method of ensuringthat a data processing (DP) accelerator signed a watermark of anartificial intelligence (AI) model, according to an embodiment.

FIGS. 4A and 4B are block diagrams illustrating a method of securelyencrypting or decrypting data using a DP accelerator having acryptographic module, according to an embodiment.

FIGS. 5A and 5B are block diagrams illustrating a method of securelyencrypting or decrypting data using a host-provided kernel and a DPaccelerator, according to an embodiment.

FIGS. 6A and 6B are block diagrams illustrating a method of securelydigitally signing an AI watermark using implicit data, according to anembodiment.

FIG. 7 is a block diagram illustrating a method of securely, digitallysigning output using a host-provided kernel according to an embodiment.

FIG. 8 is block diagram illustrating a method of securely, digitallysigning a watermark of an AI model using a watermark-enabled andsignature-enabled kernel provided by a host and an AI accelerator,according to an embodiment.

FIG. 9 is a block diagram illustrating an exemplary computing system forimplementing the functionality disclosed herein.

DETAILED DESCRIPTION

Various embodiments and aspects of the disclosures will be describedwith reference to details discussed below, and the accompanying drawingswill illustrate the various embodiments. The following description anddrawings are illustrative of the disclosure and are not to be construedas limiting the disclosure. Numerous specific details are described toprovide a thorough understanding of various embodiments of the presentdisclosure. However, in certain instances, well-known or conventionaldetails are not described in order to provide a concise discussion ofembodiments of the present disclosures.

Reference in the specification to “one embodiment” or “an embodiment”means that a particular feature, structure, or characteristic describedin conjunction with the embodiment can be included in at least oneembodiment of the disclosure. The appearances of the phrase “in oneembodiment” in various places in the specification do not necessarilyall refer to the same embodiment.

The following embodiments relate to usage of a data processing (DP)accelerator to increase processing throughput of certain types ofoperations that may be offloaded (or delegated) from a host device tothe DP accelerator. A DP accelerator can be a general-purpose processingunit (GPU), an artificial intelligence (AI) accelerator, mathcoprocessor, digital signal processor (DSP), or other type of processor.A DP accelerator can be a proprietary design, such as a Baidu® AIaccelerator, or another GPU, and the like. While embodiments areillustrated and described with host device securely coupled to one ormore DP accelerators, the concepts described herein can be implementedmore generally as a distributed processing system.

The host device and the DP accelerator can be interconnected via ahigh-speed bus, such as a peripheral component interconnect express(PCIe), or other high-speed bus. The host device and DP accelerator canexchange keys and initiate a secure channel over the PCIe bus beforeperforming operations of the aspects of the invention described below.Some of the operations include the DP accelerator using an artificialintelligence (AI) model to perform inferences using data provided by thehost device. Before the AI model inferences are trusted by the hostdevice, the host device can engage the DP accelerator to perform one ormore validation tests, described below, including determining awatermark of the AI model. In some embodiments and operations, the DPaccelerator is not aware that the host device is testing the validity ofresults produced by the DP accelerator.

A watermark of an AI model is an identifier or indicator embedded withinthe AI model, or in outputs of the AI model, or a combination thereof,that identifies or indicates the source/maker of the AI model. In someembodiments, the watermark can be a subset of coefficients or parameterssuch as weights within the AI model that, when extracted from the AImodel, comprise the watermark. Some of the goals of the watermarkinclude: identifying the AI model by its watermark; storing information,such as digital rights, within the AI model but without affectinginferences generated by the model, and associating inferences generatedby an AI model to the AI model that generated the inferences, using thewatermark as an identifier. The watermark should not be easilydiscoverable outside of a secure computing environment.

In an embodiment, the host device can send an input to the DPaccelerator that, when the DP accelerator executes the AI model usingthe input, extracts the watermark from the AI model. The host device canvalidate the watermark before using the DP accelerator and/or AI modelfor trusted operations. A watermark-enabled AI model is an AI model thatcan extract its own watermark in response to specified input data.

In some embodiments, the host device can transmit a kernel to the DPprocessing device to use in performing one or more operations. In thiscontext, a kernel is a small piece of code, provided to the DPaccelerator, to be executed by the DP accelerator to perform theintended function of the kernel. In an embodiment, a kernel is providedto the DP accelerator by the host device as a part of performingproof-of-trust operations by the DP accelerator that will be validatedby the host device. In some embodiments, the DP accelerator is not awareof the purpose of the kernel it executes on behalf of the host device.

In some embodiments, the kernel can be a “watermark-enabled kernel.” Awatermark-enabled kernel is a kernel that, when executed, is capable ofextracting a watermark from an artificial intelligence (AI) model. An AIwatermark is associated with a specific AI model and can be embedded or“implanted,” within the AI model using several different methods. Thewatermark may be implanted into one or more weight variables of the oneor more nodes of the AI model. In an embodiment, the watermark is storedin one or more bias variables of the one or more nodes of the AI modes,or by creating one or more additional nodes of the AI model during thetraining to store the watermark.

In some embodiments, the kernel can be a “watermark-inherited kernel.” Awatermark-inherited kernel is a kernel that can inherit a watermark froma data object, e.g. an existing AI model, or other data object. Thekernel can then implant the inherited watermark into another AI model oran inference generated by an AI model.

In some embodiments, the kernel can be a “signature kernel,” that candigitally sign any input that it receives. The signature kernel cangenerate a hash or digest of the input data to be signed and can embedthat hash or digest into the input to be signed before signing theinput. The hash or digest can be any hash algorithm, such as SHA-1,SHA-2, or SHA-3, et al. The input data with hash or digest can beencrypted (signed) using a private key of the data processing (DP)accelerator, a symmetric key shared with a host device, or a keyreceived from the host device.

In some embodiments, a watermark-enabled AI model is an AI model havinga watermark implanted within the AI model. In some embodiments, a hostdevice may provide a watermark-enabled kernel to the DP accelerator sothat the DP accelerator can, e.g., use an AI model to make an inference,then use the watermark-enabled kernel to extract the watermark from theAI model, embed the watermark in the inference, and digitally sign theinference. Such an embodiment allows the host device to verify that theDP accelerator did, indeed, use the correct AI model to perform theinference, indicating that the inference may be trusted.

With respect to any of the following aspects, in one embodiment, awatermark may be embedded in one or more nodes of one or more layers ofan artificial intelligence (AI) model. For example, a watermark may beimplanted in one or more weight variables or bias variables.Alternatively, one or more nodes (e.g., fake nodes that are not used orunlikely used by the artificial intelligence model) may be created toimplant or store the watermark. A host processor may be a centralprocessing unit (CPU) and a DP accelerator may be a general-purposeprocessing unit (GPU) coupled to the CPU over a bus or interconnect. ADP accelerator may be implemented in a form of an application-specificintegrated circuit (ASIC), a field programmable gate array (FPGA)device, or other forms of integrated circuits (ICs). Alternatively, thehost processor may be a part of a primary data processing system while aDP accelerator may be one of many distributed systems as secondarysystems that the primary system can offload its data processing tasksremotely over a network (e.g., cloud computing systems such as asoftware as a service or SaaS system, or a platform as a service or PaaSsystem). A link between a host processor and a DP accelerator may be aperipheral component interconnect express (PCIe) link or a networkconnection such as Ethernet connection.

In a first aspect, a computer-implemented method of a data processing(DP) accelerator obtaining a watermark of a watermark-enable artificialintelligence (AI) model includes receiving, by the DP accelerator, inputdata to the DP accelerator that causes the watermark-enabled AI model toextract the watermark from the watermark-enabled AI model; and providingthe watermark of the watermark-enabled AI model to the host device. TheDP accelerator can receive the model from the host device. The DPaccelerator can further receive a command to digitally sign thewatermark and call a security unit of the DP accelerator to digitallysign the watermark.

In a second aspect, a computer-implemented method of a DP acceleratorperforming an encryption or decryption operation includes receiving, bythe DP accelerator, a command and input data for the DP accelerator toencrypt or decrypt. The command is one of: encrypt the input data ordecrypt the input data. The method further includes encrypting, ordecrypting, by the DP accelerator, the input data according to thecommand; and providing the encrypted or decrypted input data to the hostdevice. The host device and DP accelerator may exchange one or more keysand such keys can be used to establish a secure link between the hostdevice and DP accelerator and/or to use for encryption or decryption.One or more of the keys may be based upon a root key or key pair of theDP accelerator and can be stored in a secure storage of a security unitof the DP accelerator.

In a third aspect, a computer-implemented method of a data processing(DP) accelerator encrypting or decrypting input data can includereceiving, from a host device, a command, the input data, and a kernel.The kernel can be an encryption kernel, or a decryption kernel, and theDP accelerator need not know which kernel it has received. The DPaccelerator runs the received kernel. In response to the DP acceleratorreceiving the command, the DP accelerator performs encrypting of theinput data using the kernel, if the received kernel is an encryptionkernel, otherwise, decrypting the input data using the kernel. Theencrypted, or decrypted, input data is then provided to the host device.The host device and DP accelerator may exchange one or more keys andsuch keys can be used to establish a secure link between the host deviceand DP accelerator and/or to use for encryption or decryption. One ormore of the keys may be based upon a root key or key pair of the DPaccelerator and can be stored in a secure storage of a security unit ofthe DP accelerator.

In a fourth aspect, a computer-implemented method of a data processing(DP) accelerator obtaining a watermark of an artificial intelligence(AI) model includes receiving, from a host device, the AI model toexecute on the DP accelerator, and receiving input data that triggersoutput from the AI model on the DP accelerator. The DP acceleratorcalculates AI model output, in response to the received input andprovides the output to the host device. The output can be a watermarkextracted from the AI model. DP accelerator can call a security unit ofthe DP accelerator to digitally sign the output. In an embodiment, thesecurity unit digitally signs the output from the AI model using a keythat is retrieved from, or is derived from, a key stored in a securestorage on the security unit.

In a fifth aspect, a computer-implemented method of digitally signinginput by a data processing (DP) accelerator operation, and embedding thedigitally signed input into an output, includes receiving, from a hostdevice, a signature kernel specifying input to the signature kernel andexecuting the signature kernel to: extract a watermark from the inputand obtain a hash for the watermark; generate output from the input; andembed the hash into the output. The DP accelerator provides the outputto the host device. In an embodiment, the input includes an artificialintelligence (AI) model that is executed by the DP accelerator. The DPaccelerator receives second input from the host, thereby producing aninference output from the AI model. The digitally signed watermark ofthe AI Model is embedded into the inference output and is provided tothe host device.

In a sixth aspect, a computer implemented method of a data processing(DP) accelerator providing a watermark of an artificial intelligence(AI) model to a host device includes receiving, by the DP accelerator,from the host device, the AI model, and a watermark-enabled kernel tothe DP accelerator. The DP accelerator further receives from the hostdevice, first input data to the DP accelerator that, when the firstinput data is used as input to the watermark-enabled kernel, generates awatermark of the AI model. The watermark is provided to the host device.In an embodiment, the method further includes receiving a signaturekernel from the host device and calling the signature kernel todigitally sign the watermark. In an embodiment, the method alternativelyincludes calling a digital signature routine in a secure unit of the DPaccelerator to digitally sign the watermark.

Any of the above functionality can be programmed as executableinstructions onto one or more non-transitory computer-readable media.When the executable instructions are executed by a processing systemhaving at least one hardware processor, the processing systems causesthe functionality to be implemented. Any of the above functionality canbe implemented by a processing system having at least one hardwareprocessor, coupled to a memory programmed with executable instructionsthat, when executed, cause the processing system to implement thefunctionality.

FIG. 1 is a block diagram illustrating an example of systemconfiguration for securing communication between a host 104 and dataprocessing (DP) accelerators 105-107 according to some embodiments.Referring to FIG. 1 , system configuration 100 includes, but is notlimited to, one or more client devices 101-102 communicatively coupledto DP server 104 (e.g. host) over network 103. Client devices 101-102may be any type of client devices such as a personal computer (e.g.,desktops, laptops, and tablets), a “thin” client, a personal digitalassistant (PDA), a Web enabled appliance, a Smart watch, or a mobilephone (e.g., Smartphone), etc. Alternatively, client devices 101-102 maybe other servers. Network 103 may be any type of networks such as alocal area network (LAN), a wide area network (WAN) such as theInternet, or a combination thereof, wired or wireless.

Server (e.g., host) 104 may be any kind of servers or a cluster ofservers, such as Web or cloud servers, application servers, backendservers, or a combination thereof. Server 104 further includes aninterface (not shown) to allow a client such as client devices 101-102to access resources or services (such as resources and services providedby DP accelerators via server 104) provided by server 104. For example,server 104 may be a cloud server or a server of a data center thatprovides a variety of cloud services to clients, such as, for example,cloud storage, cloud computing services, artificial intelligencetraining services, data mining services, etc. Server 104 may beconfigured as a part of software-as-a-service (SaaS) orplatform-as-a-service (PaaS) system over the cloud, which may be aprivate cloud, public cloud, or a hybrid cloud. The interface mayinclude a Web interface, an application programming interface (API),and/or a command line interface (CLI).

For example, a client, in this example, a user application of clientdevice 101 (e.g., Web browser, application), may send or transmit aninstruction (e.g., AI training, inference instruction, etc.) forexecution to server 104 and the instruction is received by server 104via the interface over network 103. In response to the instruction,server 104 communicates with DP accelerators 105-107 to fulfill theexecution of the instruction. In some embodiments, the instruction is amachine learning type of instruction where DP accelerators, as dedicatedmachines or processors, can execute the instruction many times fasterthan execution by server 104. Server 104 thus can control/manage anexecution job for the one or more DP accelerators in a distributedfashion. Server 104 then returns an execution result to client devices101-102. A DP accelerator or AI accelerator may include one or morededicated processors such as a Baidu® artificial intelligence (AI)chipset available from Baidu, Inc.® or alternatively, the DP acceleratormay be an AI chipset from another AI chipset provider.

According to one embodiment, each of the applications accessing any ofDP accelerators 105-107 hosted by data processing server 104 (alsoreferred to as a host) may verify that the application is provided by atrusted source or vendor. Each of the applications may be launched andexecuted within a trusted execution environment (TEE) specificallyconfigured and executed by a central processing unit (CPU) of host 104.When an application is configured to access any one of the DPaccelerators 105-107, an obscured connection can be established betweenhost 104 and the corresponding one of the DP accelerator 105-107, suchthat the data exchanged between host 104 and DP accelerators 105-107 isprotected against attacks from malware/intrusions.

FIG. 2A is a block diagram illustrating an example of a multi-layerprotection solution for obscured communications between a host system104 and data process (DP) accelerators 105-107 according to someembodiments. In one embodiment, system 200 provides a protection schemefor obscured communications between host 104 and DP accelerators 105-107with or without hardware modifications to the DP accelerators. Referringto FIG. 2A, host machine or server 104 can be depicted as a system withone or more layers to be protected from intrusion such as userapplication(s) 205, runtime libraries 206, driver 209, operating system211, and hardware 213 (e.g., security module (trusted platform module(TPM))/central processing unit (CPU)). Memory safe applications 207 canrun in a sandboxed memory. Below the applications 205 and run-timelibraries 206, one or more drivers 209 can be installed to interface tohardware 213 and/or to DP accelerators 105-107.

Hardware 213 can include one or more processor(s) 201 and storagedevice(s) 204. Storage device(s) 204 can include one or more artificialintelligence (AI) models 202, and one or more kernels 203. Kernels 203can include signature kernels, watermark-enabled kernels, encryptionand/or decryption kernels, and the like. A signature kernel, whenexecuted, can digitally sign any input in accordance with theprogramming of the kernel. A watermark-enabled kernel can extract awatermark from a data object (e.g. an AI model or other data object). Awatermark-enabled kernel can also implant a watermark into an AI model,an inference output, or other data object. A watermark kernel (e.g. awatermark inherited kernel) can inherit a watermark from another dataobject and implant that watermark into a different object, such as aninference output or an AI model. A watermark, as used herein, is anidentifier associated with, and can be implanted into, an AI model or aninference generated by an AI model. For example, a watermark may beimplanted in one or more weight variables or bias variables.Alternatively, one or more nodes (e.g., fake nodes that are not used orunlikely used by the artificial intelligence model) may be created toimplant or store the watermark.

Host machine 104 is typically a CPU system which can control and manageexecution of jobs on the host machine 104 and/or DP accelerators105-107. In order to secure/obscure a communication channel 215 betweenDP accelerators 105-107 and host machine 104, different components maybe required to protect different layers of the host system that areprone to data intrusions or attacks. For example, a trusted executionenvironment (TEE) can protect the user application 205 layer and theruntime library 206 layer from data intrusions.

System 200 includes host system 104 and DP accelerators 105-107according to some embodiments. DP accelerators can include Baidu® AIchipsets or another AI chipset such as a graphical processing units(GPUs) that can perform artificial intelligence (AI)-intensive computingtasks. In one embodiment, host system 104 includes a hardware that hasone or more CPU(s) 213 equipped with a security module (such as atrusted platform module (TPM)) within host machine 104. A TPM is aspecialized chip on an endpoint device that stores cryptographic keys(e.g., RSA cryptographic keys) specific to the host system for hardwareauthentication. Each TPM chip can contain one or more RSA key pairs(e.g., public and private key pairs) called endorsement keys (EK) orendorsement credentials (EC), i.e., root keys. The key pairs aremaintained inside the TPM chip and cannot be accessed by software.Critical sections of firmware and software can then be hashed by the EKor EC before they are executed to protect the system againstunauthorized firmware and software modifications. The TPM chip on thehost machine can thus be used as a root of trust for secure boot.

The TPM chip also secure driver(s) 209 and operating system (OS) 211 ina working kernel space to communicate with the DP accelerators 105-107.Here, driver 209 is provided by a DP accelerator vendor and can serve asa driver for the user application to control a communication channel(s)215 between host and DP accelerators. Because the TPM chip and secureboot processor protects the OS 211 and drivers 209 in their kernelspace, TPM also effectively protects the driver 209 and OS 211.

Since communication channels 215 for DP accelerators 105-107 may beexclusively occupied by the OS 211 and driver 209, thus, communicationchannels 215 can be secured through the TPM chip. In one embodiment,communication channels 215 include a peripheral component interconnector peripheral component interconnect express (PCIE) channel. In oneembodiment, communication channels 215 are obscured communicationchannels.

Host machine 104 can include trusted execution environment (TEE) 210which is enforced to be secure by TPM/CPU 213. A TEE is a secureenvironment. TEE can guarantee code and data which are loaded inside theTEE to be protected with respect to confidentiality and integrity.Examples of a TEE may be Intel® software guard extensions (SGX), or AMD®secure encrypted virtualization (SEV). Intel® SGX and/or AMD® SEV caninclude a set of central processing unit (CPU) instruction codes thatallows user-level code to allocate private regions of memory of a CPUthat are protected from processes running at higher privilege levels.Here, TEE 210 can protect user applications 205 and runtime libraries206, where user application 205 and runtime libraries 206 may beprovided by end users and DP accelerator vendors, respectively. Here,runtime libraries 206 can convert application programming interface(API) calls to commands for execution, configuration, and/or control ofthe DP accelerators. In one embodiment, runtime libraries 206 provides apredetermined set of (e.g., predefined) kernels for execution by theuser applications. In an embodiment, the kernels may be stored instorage device(s) 204 as kernels 203.

Host machine 104 can include memory safe applications 207 which areimplemented using memory safe languages such as Rust, and GoLang, etc.These memory safe applications running on memory safe Linux® releases,such as MesaLock Linux®, can further protect system 200 from dataconfidentiality and integrity attacks. However, the operating systemsmay be any Linux® distributions, UNIX®, Windows® OS, or Mac® OS.

The host machine 104 can be set up as follows: A memory safe Linux®distribution is installed onto a system equipped with TPM secure boot.The installation can be performed offline during a manufacturing orpreparation stage. The installation can also ensure that applications ofa user space of the host system are programmed using memory safeprogramming languages. Ensuring other applications running on hostsystem 104 to be memory safe applications can further mitigate potentialconfidentiality and integrity attacks on host system 104.

After installation, the system can then boot up through a TPM-basedsecure boot. The TPM secure boot ensures only a signed/certifiedoperating system and accelerator driver are launched in a kernel spacethat provides the accelerator services. In one embodiment, the operating211 system can be loaded through a hypervisor (not shown). A hypervisoror a virtual machine manager is a computer software, firmware, orhardware that creates and runs virtual machines. A kernel space is adeclarative region or scope where kernels (i.e., a predetermined set of(e.g., predefined) functions for execution) are identified to providefunctionalities and services to user applications. In the event thatintegrity of the system is compromised, TPM secure boot may fail to bootup and instead shuts down the system.

After secure boot, runtime libraries 206 runs and creates TEE 210, whichplaces runtime libraries 206 in a trusted memory space associated withCPU 213. Next, user application 205 is launched in TEE 210. In oneembodiment, user application 205 and runtime libraries 206 arestatically linked and launched together. In another embodiment, runtimelibrary 206 is launched in TEE 211) first and then user application 205is dynamically loaded in TEE 210. In another embodiment, userapplication 205 is launched in TEE first, and then runtime 206 isdynamically loaded in TEE 210. Statically linked libraries are librarieslinked to an application at compile time. Dynamic loading can beperformed by a dynamic linker. Dynamic linker loads and links sharedlibraries for running user applications at runtime. Here, userapplications 205 and runtime libraries 206 within TEE 210 are visible toeach other at runtime, e.g., all process data are visible to each other.However, external access to the TEE is denied.

In one embodiment, the user application 205 can only call a kernel froma set of kernels as predetermined by runtime libraries 206. In anotherembodiment, user application 205 and runtime libraries 206 are hardenedwith side channel free algorithm to defend against side channel attackssuch as cache-based side channel attacks. A side channel attack is anyattack based on information gained from the implementation of a computersystem, rather than weaknesses in the implemented algorithm itself (e.g.cryptanalysis and software bugs). Examples of side channel attacksinclude cache attacks which are attacks based on an attacker's abilityto monitor a cache of a shared physical system in a virtualizedenvironment or a cloud environment. Hardening can include masking of thecache, outputs generated by the algorithms to be placed on the cache.Next, when the user application finishes execution, the user applicationterminates its execution and exits from the TEE.

In one embodiment, TEE 210 and/or memory safe applications 207 is notnecessary, e.g., user application 205 and/or runtime libraries 206 ishosted in an operating system environment of host 104.

In one embodiment, the set of kernels include obfuscation kernelalgorithms. In one embodiment, the obfuscation kernel algorithms can besymmetric or asymmetric algorithms. A symmetric obfuscation algorithmcan obfuscate and de-obfuscate data communications using a samealgorithm. An asymmetric obfuscation algorithm requires a pair ofalgorithms, where a first of the pair is used to obfuscate and thesecond of the pair is used to de-obfuscate, or vice versa. In anotherembodiment, an asymmetric obfuscation algorithm includes a singleobfuscation algorithm used to obfuscate a data set but the data set isnot intended to be de-obfuscated, e.g., there is absent a counterpartde-obfuscation algorithm.

Obfuscation refers to obscuring of an intended meaning of acommunication by making the communication message difficult tounderstand, usually with confusing and ambiguous language. Obscured datais harder and more complex to reverse engineering. An obfuscationalgorithm can be applied before data is communicated to obscure(cipher/decipher) the data communication reducing a chance of eavesdrop.In one embodiment, the obfuscation algorithm can further include anencryption scheme to further encrypt the obfuscated data for anadditional layer of protection. Unlike encryption, which may becomputationally intensive, obfuscation algorithms may simplify thecomputations.

Some obfuscation techniques can include but are not limited to, letterobfuscation, name obfuscation, data obfuscation, control flowobfuscation, etc. Letter obfuscation is a process to replace one or moreletters in a data with a specific alternate letter, rendering the datameaningless. Examples of letter obfuscation include a letter rotatefunction, where each letter is shifted along, or rotated, a predeterminenumber of places along the alphabet. Another example is to reorder orjumble up the letters based on a specific pattern. Name obfuscation is aprocess to replace specific targeted strings with meaningless strings.Control flow obfuscation can change the order of control flow in aprogram with additive code (insertion of dead code, insertinguncontrolled jump, inserting alternative structures) to hide a truecontrol flow of an algorithm/AI model.

In summary, system 200 provides multiple layers of protection for DPaccelerators (for data transmissions including machine learning models,training data, and inference outputs) from loss of data confidential andintegrity. System 200 can include a TPM-based secure boot protectionlayer, a TEE protection layer, and a kernel validation/verificationlayer. Furthermore, system 200 can provide a memory safe user space byensuring other applications on the host machine are implemented withmemory safe programming languages, which can further eliminate attacksby eliminating potential memory corruptions/vulnerabilities. Moreover,system 200 can include applications that use side-channel freealgorithms so to defend against side channel attacks, such as cachebased side channel attacks.

Runtime 206 can provide obfuscation kernel algorithms to obfuscate datacommunication between a host 104 and DP accelerators 105-107. In oneembodiment, the obfuscation can be pair with a cryptography scheme. Inanother embodiment, the obfuscation is the sole protection scheme andcryptography-based hardware is rendered unnecessary for the DPaccelerators.

FIG. 2B is a block diagram illustrating an example of a host channelmanager (HCM) 259 communicatively coupled to one or more acceleratorchannel managers (ACMs) 270 that interface to DP accelerators 105-107,according to some embodiments. Referring to FIG. 2B, in one embodiment,HCM 259 includes authentication module 251, termination module 252, keymanager 253, key(s) store 254, and cryptography engine 255.Authentication module 251 can authenticate a user application running onhost server 104 for permission to access or use a resource of a DPaccelerator 105.

Termination module 252 can terminate a connection (e.g., channelsassociated with the connection would be terminated). Key manager 253 canmanage (e.g., create or destroy) asymmetric key pairs or symmetric keysfor encryption/decryption of one or more data packets for differentsecure data exchange channels. Here, each user application (as part ofuser applications 205 of FIG. 2A) can correspond or map to differentsecure data exchange channels, on a one-to-many relationship, and eachdata exchange channel can correspond to a DP accelerator 105. Eachapplication can utilize a plurality of session keys, where each sessionkey is for a secure channel corresponding to a DP accelerator (e.g.,accelerators 105 . . . 107). Key(s) store 254 can store encryptionasymmetric key pairs or symmetric keys. Cryptography engine 255 canencrypt or decrypt a data packet for the data exchanged through any ofthe secure channels. Note that some of these modules can be integratedinto fewer modules.

In one embodiment, DP accelerator 105 includes ACM 270 and security unit(SU) 275. Security unit 275 can include key manager 271, key(s) store272, true random number generator 273, and cryptography engine 274. Keymanager 271 can manage (e.g., generate, safe keep, and/or destroy)asymmetric key pairs or symmetric keys. Key(s) store 272 can store thecryptography asymmetric key pairs or symmetric keys in secure storagewithin the security unit 275. True random number generator 273 cangenerate seeds for key generation and cryptographic engine 274 uses.Cryptography engine 274 can encrypt or decrypt key information or datapackets for data exchanges. In some embodiments, ACM 270 and SU 275 isan integrated module.

DP accelerator 105 can further includes memory/storage 280 that canstore artificial intelligence model(s) 277, watermark kernel(s) 278(including inherited watermark kernels watermark-enabled kernels,watermark-signature kernels, et al.), encryption and decryption kernels281, and data 279. HCM 259 can communicate with ACM 270 viacommunication channel 215.

In one embodiment, DP accelerator 105 further includes an AI unit, whichmay include an AI training unit and an AI inference unit. The AItraining and inference units may be integrated into a single unit. TheAI training module is configured to train an AI model using a set oftraining data. The AI model to be trained and the training data may bereceived from host system 104 via communication link 215. The AI modelinference unit can be configured to execute a trained artificialintelligence model on a set of input data (e.g., set of input features)to infer and classify the input data. For example, an image may be inputto an artificial intelligence model to classify whether the imagecontains a person, a landscape, etc. The trained artificial intelligencemodel and the input data may also be received from host system 104 viainterface 140 over communication link 215.

In one embodiment, watermark unit 276 may include a watermark generator,and a watermark inscriber (also termed, “watermark implanter”).Watermark unit 276 may include a watermark kernel executor or kernelprocessor (not shown) to execute a kernel. In an embodiment, a kernelmay be received from host 104, or retrieved from persistent ornon-persistent storage, and executed in memory (not shown) of DPaccelerator 105. The watermark generator is configured to generate awatermark using a predetermined watermark algorithm. Alternatively, thewatermark generator can inherit a watermark from an existing watermarkor extract a watermark from another data structure or data object, suchas an artificial intelligence model or a set of input data, which may bereceived from host system 104. The watermark implanter is configured toinscribe or implant a watermark into a data structure such as anartificial intelligence model or output data generated by an artificialintelligence model. The artificial intelligence model or output datahaving a watermark implanted therein may be returned from DP accelerator105 to host system 104 over communication link 215. Note that DPaccelerators 105-107 have the identical or similar structures orcomponents and the description concerning a DP accelerator would beapplicable to all DP accelerators throughout this application.

FIGS. 3A and 3B are block diagrams illustrating a method 300 of signinga watermark of an artificial intelligence (AI) model, using a query,according to an embodiment. A purpose of method 300 is to provide ageneric watermark signature method to prove that the AI model is indeedused by the DP accelerator 105. In preparation for method 300, hostdevice 104 and DP accelerator 105 may exchange one or more designatedkeys and establish a secure communication link 215. One or more of theexchanged keys may also be used to digitally sign the watermarkextracted from the AI model. In an embodiment, communications betweenhost device 104 and DP accelerator 105 use encryption and decryption tomaintain secure communications over communication link 215. Embodimentsaccording to method 300 can use a data processing (DP) accelerator 105such as Baidu® AI accelerator or other DP accelerator, or an acceleratorsuch as a graphics processing unit (GPU).

Referring now to FIG. 3A, a method 300 of producing a valid watermarkfrom an AI model is described according to one embodiment. In operation305, an application on host device 104 sends a watermark-enabled AImodel to DP accelerator 105. In operation 350 DP accelerator 105receives the watermark-enabled AI model and loads the watermark-enabledAI model for execution.

In operation 310, the application on host device 104 sends input data,which can be in the form of a query, to DP accelerator 105. In operation355, DP accelerator receives the input data from host device 104 and, inoperation 360, DP accelerator runs the AI model using input data toextract the watermark from the watermark-enabled AI model.

In operation 325, host device 104 can retrieve the watermark from the DPaccelerator 105, that DP accelerator 105 has made available to the hostdevice 104, in operation 375. The host device 104 can optionallyvalidate the received watermark before making further calls to the DPaccelerator 105 to perform operations in accordance with method 300. Inoperation 325, host device 104 can perform one or more validationoperations on the watermark to ensure that the watermark extracted fromthe watermark-enabled AI model is valid. The host device 104 may comparethe watermark obtained from the DP accelerator 105 with a pre-existingwatermark to determine whether the watermark received from the DPaccelerator 105 is valid.

Alternatively, in an embodiment, host device 104 can validate thewatermark by running the watermark-enabled AI model with the input datato obtain the watermark and comparing the obtained watermark with thewatermark received from the DP accelerator 105. If the two watermarksmatch, then the DP accelerator 105 used the watermark-enabled AI modelto produce the watermark, and the watermark is determined to be valid.If the watermark is valid, then the application on host device 104 canmake one or more additional calls to DP accelerator 105 using thewatermark-enabled AI model, such as to perform one or more inferencesusing the watermark-enabled AI model. In operation 330, host 104 canmake one or more calls to DP accelerator to perform operations of method300.

Referring now to FIG. 3B, FIG. 3B describes a method 300 of extracting awatermark from an artificial intelligence (AI) model and digitallysigning the watermark.

In operation 305, an application on host device 104 sends awatermark-enabled AI model to DP accelerator 105. In operation 350, DPaccelerator 105 receives the watermark-enabled AI model and loads thewatermark-enabled AI model for execution.

In operation 310, host device 104 sends input data, which can be in theform of a query, to DP accelerator 105. In operation 355, DP acceleratorreceives the input data from host device 104 and, in operation 360, DPaccelerator runs the watermark-enabled AI model using the input data toextract the watermark of the watermark-enabled AI model.

In operation 370, DP accelerator 105 calls security unit 275 todigitally sign the watermark. In an embodiment, the watermark can bedigitally signed with a private key of the DP accelerator, or with asymmetric key. The private key of the DP accelerator, or the symmetrickey, can be one of the one more keys exchanged with the host device 104and DP accelerator 105, as described above. In an embodiment, digitallysigning the watermark by the security unit 275 of DP accelerator 105includes computing a hash or digest of the watermark and including thehash or digest with the digitally signed watermark.

In operation 325, host device 104 can retrieve the digitally signedwatermark from the DP accelerator 105, that DP accelerator 105 has madeavailable to the host device 104, in operation 375. The host device 104can optionally validate the received watermark before making furthercalls to the DP accelerator 105 to perform operations in accordance withmethod 300. Host device 104 can perform one or more validationoperations on the digitally signed watermark. The host device 104 maycompare the watermark obtained from the DP accelerator 105 with apre-existing watermark to determine whether the watermark received fromthe DP accelerator 105 is valid.

Alternatively, in an embodiment, host 104 can decrypt the digitalsignature on the watermark using a public key of the DP accelerator 105,or a symmetric key. After decrypting the digital signature, host device104 can verify the unsigned watermark by running the watermark-enabledAI model with the input data to extract the watermark and comparing theextracted watermark with the watermark received from the DP accelerator105. If the two watermarks match, then the DP accelerator 105 used thewatermark-enabled AI model to produce the watermark and the digitalsignature was determined to be valid. In operation 330, the applicationon host device 104 can make one or more additional calls to DPaccelerator 105 that utilize the watermark-enabled AI model.

FIGS. 4A and 4B are block diagrams illustrating a method 400 of securelyencrypting or decrypting data using a data processing (DP) accelerator,according to some embodiments. In preparation for method 400, hostdevice 104 and DP accelerator 105 can exchange one or more designatedkeys and establish a secure communication channel 215 for communicating.Embodiments according to method 400 can use, as a DP accelerator 105, anaccelerator such as Baidu® artificial intelligence (AI) accelerator orother AI accelerator, or a graphics processing unit (GPU).

Referring now to FIG. 4A, in operations 405 and 450, host device 104 andDP accelerator 105 can exchange one or more designated keys. Thedesignated keys can include one or more symmetric keys and/or one ormore asymmetric key pairs. A symmetric key can be used for securecommunication sessions between the host device 104 and DP accelerator105 over communications channel 215. Asymmetric keys can be used forencrypting and decrypting data and digital signatures. In an embodiment,sharing designated keys comprises the host device 104 sharing a publickey of the host device 104 with the DP accelerator 105 and the DPaccelerator 105 sharing a public key of the DP accelerator with the hostdevice 104.

In operation 410, an application on the host device 104 sends a commandand data to the DP accelerator 105, to encrypt or decrypt using one ofthe designated keys. In operation 455, DP accelerator 105 receives thecommand (encrypt or decrypt) and data to be encrypted or decrypted bythe DP accelerator 105, using the designated key.

In operation 475, a cryptographic engine 274 of DP accelerator securityunit 275 encrypts, or decrypts, the data received from host device 104in accordance with the command received from host device 104. DPaccelerator 105 makes the encrypted, or decrypted, data available tohost device 104. In operation 420, host device 104 can retrieve theencrypted, or decrypted, data from DP accelerator 105.

In operation 425, an application on host device 104 can optionallyvalidate the received encrypted or decrypted data. If the command was“encrypt,” then the host device 104 can decrypt the received encrypteddata using a public key of the DP accelerator 105. The host device canthen compare the decrypted data to the clear-text input data sent to theDP accelerator to encrypt. If the comparison is a match, then theencryption operation is validated. If the command was “decrypt” then thehost device 104 can compare the clear-text of the input data encrypteddata sent to the DP accelerator 105 against the decrypted data receivedfrom the DP accelerator.

Alternatively, in an embodiment, host device 104 can decrypt theclear-text data that the host device 104 previously sent to the DPaccelerator 105 to decrypt. Host device 104 can compare the result ofthe clear-text input of the encrypted data sent to the DP accelerator,or the host decrypting the encrypted data, with the decrypted datareturned to the host device 104 by DP accelerator 105. If the comparisonis a match, then the decryption operation is validated.

In operation 430, Host device 104 can request one or more additionalencryption or decryption operations from the DP accelerators 150. In anembodiment, if the encryption or decryption operation was not validated,then host device 104 can opt to not make additional encryption ordecryption calls to DP accelerator 105. Method 400 ends.

Referring now to FIG. 4B, in operation 410, an application on the hostdevice 104 sends a command and data to the DP accelerator 105 to encryptthe data. In operation 455, DP accelerator 105 receives the encryptioncommand and data to be encrypted by the DP accelerator 105.

In operation 465, the DP accelerator 105 generates a new symmetric keyor asymmetric key pair using the security unit 275. DP accelerator 105transmits a key (e.g. a public key of a newly generated asymmetric keypair) to the host device 104. In operation 415, host device 104 receivesthe key from DP accelerator 105.

In operation 475, a cryptographic engine 274 of DP accelerator securityunit 275 encrypts the data received from host device 104 in accordancewith the command received from host device 104. DP accelerator 105 canencrypt the data with, e.g., a private key of an asymmetric key pairgenerated in operation 465, above. DP accelerator 105 makes theencrypted data available to host device 104. In operation 420, hostdevice 104 can retrieve the encrypted data from DP accelerator 105.

In operation 425, an application on host device 104 can optionallyvalidate the received encrypted data. The host device 104 can decryptthe received encrypted data using a public key of the DP accelerator105. The host device 104 can then compare the decrypted data to theclear-text input data sent to the DP accelerator to encrypt. If thecomparison is a match, then the encryption operation was validated.

In operation 430, host device 104 can request one or more encryptionoperations from the DP accelerator 105. In an embodiment, if theencryption operation was not validated, then host device 104 can opt tonot make additional encryption calls to DP accelerator 105. Method 400ends.

FIGS. 5A and 5B are block diagrams illustrating a method 500 ofencrypting or decrypting data using a host-provided encryption kernel,or decryption kernel, and a DP accelerator 105, according to anembodiment. The DP accelerator can be a Baidu® artificial intelligence(AI) processor, a graphics processing unit (GPU), a multi-coreprocessor, a DSP processor, or other DP accelerator.

Referring now to FIG. 5A, in operations 505 and 550, host device 104 andDP accelerator 105 can exchange one or more designated keys. Thedesignated keys can include one or more symmetric keys and/or one ormore asymmetric keys. A symmetric key can be used for communicationsessions between the host device 104 and DP accelerator 105 overcommunications channel 215. Asymmetric keys can be used for encryptingand decrypting data and digital signatures. In an embodiment, sharingdesignated keys comprises the host device 104 sharing a public key ofthe host device 104 with the DP accelerator 105 and the DP accelerator105 sharing a public key of the DP accelerator with the host device 104.

In operation 512, an application on host device 104 can transmit to theDP accelerator an encryption kernel or a decryption kernel, a command toexecute the kernel, and input data to be encrypted or decrypted. Inoperation 557, the DP accelerator 105 receives the encryption kernel ordecryption kernel, input data, and command to execute the kernel usingthe input data, from the host device 104.

In operation 565, the DP accelerator 105 runs the received kernel, inresponse to the command, and using the command to either encrypt ordecrypt (depending upon which kernel was received by the DP accelerator105) the input data using the designated key.

In operation 570, DP accelerator 105 can provide the resultant output ofrunning the encryption kernel or the decryption kernel with the commandand input data, to the host device 104. In operation 522, the hostdevice 104 can retrieve the resultant data from the DP accelerator 105and, optionally, validate the retrieved resultant data. If the kerneltransmitted to the DP accelerator was an encryption kernel, then hostdevice 104 can decrypt the resultant data received from DP accelerator105 using the designated key, or a key corresponding to the designatedkey in a key pair. Host device 104 can compare the decrypted resultantdata to the clear-text of the input data sent to DP accelerator 105 forencryption.

If the decrypted resultant data received from the DP accelerator matchesthe clear-text input data transmitted by the host device 104 to the DPaccelerator 105 in operation 512, then the encryption operation by theDP accelerator is valid. If the kernel received by the DP acceleratorwas a decryption kernel, then host device 104 can decrypt the input datathat host device 104 transmitted to DP processor 150 in operation 512.Host device 104 can compare the decrypted input data with the resultantdata received from DP accelerator 105. If the resultant data receivedfrom DP accelerator 105 matches the input data decrypted by the hostdevice 104 then the decryption operation is valid.

In operation 530, host device 104 can make one or more additional callsfor encryption/decryption operations using the encryption or decryptionkernel on the DP accelerator 105. In an embodiment, if the encryption ordecryption operation was not validated, host 104 can opt to not makefuture calls for encryption or decryption operations to DP accelerator105 using method 500.

Referring now to FIG. 5B, in operation 507, an application on hostdevice 104 transmits input data to be encrypted or decrypted to DPaccelerator 105. In operation 551, DP accelerator 105 receives the inputdata from host device 104. In operation 510, an application on hostdevice 104 can transmit to the DP accelerator 105 an encryption kernelor a decryption kernel, a command to execute the kernel, and a key to beused for encryption or decryption by the DP accelerator 105. Inoperation 557, the DP accelerator 105 receives the encryption kernel ordecryption kernel, the command to execute the kernel, and the key to usefor encrypting or decrypting the input data, from the host device 104.

In operation 565, the DP accelerator 105 runs the received encryptionkernel or decryption kernel, in response to the command, and using thecommand to either encrypt or decrypt the input data using the keyreceived from the host 104 (depending upon which kernel was received bythe DP accelerator 105).

In operation 570, DP accelerator 105 can provide the resultant output ofrunning the encryption kernel or the decryption kernel with the command,the received key, and the input data, to the host device 104. Inoperation 522, the host device 104 can retrieve the resultant data fromthe DP accelerator 105 and, optionally, validate the retrieved resultantdata. If the kernel transmitted to the DP accelerator 105 was anencryption kernel, then host device 104 can decrypt the resultant datareceived from DP accelerator 105 using a key corresponding to the keytransmitted to the DP accelerator in operation 510, above.

In an embodiment, the key used by the host 104 to decrypt the resultantdata received from the DP accelerator 105 is a private key correspondingto a public key transmitted to the DP accelerator 105. Host device 104can compare the decrypted resultant data to the clear-text of the inputdata sent to DP accelerator 105 for encryption. If the decryptedresultant data received from the DP accelerator matches the clear-textinput data transmitted by the host device 104 to the DP accelerator 105in operation 512, then the encryption operation by the DP accelerator isvalid.

If the kernel received by the DP accelerator was a decryption kernel,then host device 104 can decrypt the input data that host device 104transmitted to DP processor 150 in operation 512. Host device 104 cancompare the decrypted input data with the resultant data received fromDP accelerator 105. If the resultant data received from DP accelerator105 matches the input data decrypted by the host device 104 then thedecryption operation is valid.

In operation 530, host device 104 can call DP accelerator 105 for one ormore additional encryption/decryption operations using the encryptionkernel or decryption kernel on the DP accelerator 105. In an embodiment,if the encryption or decryption operation was not validated, host 104can opt to not make future calls for encryption or decryption operationsto DP accelerator 105 using method 500.

FIGS. 6A and 6B are block diagrams illustrating a method 600 of signingan AI watermark using implicit data, according to an embodiment.Referring now to FIG. 6A, in operation 605, an application on hostdevice 104 can transmit an artificial intelligence (AI) model to the DPaccelerator 105. In operation 650, the DP accelerator can receive the AImodel from the host device 104.

In operation 610, the application on the host device 104 can transmitinput to the DP accelerator that is used to trigger output from the AImodel. In operation 655, DP accelerator 105 can receive the input datafrom the host device 104. In operation 660, DP accelerator 105 can runthe AI model with the received input data to produce an output data. Theoutput data can be a watermark of the AI model.

In operation 680, the DP accelerator can make the output data availableto the host device 104 for retrieval. In operation 620, host device 104can retrieve and, optionally, validate the output from the DPaccelerator running the AI model with the input data. To validate theoutput data, host device 104 can run the AI model with the input data toobtain the watermark from the AI model, or otherwise obtain thewatermark from a pre-existing source, and compare the obtained AI modelwatermark with the output data received from the DP accelerator 105. Ifthe obtained watermark matches the output data received from DPaccelerator 105, then the watermark is valid operation by the DPaccelerator is valid.

In operation 625, host device 104 can request additional data processingoperations from DP accelerator 105 using the AI model. In an embodiment,if the watermark was not validated, host 104 can opt to not make futurecalls to the DP accelerator 105 using method 600.

Referring now to FIG. 6B, in operation 605, an application on hostdevice 104 can transmit an AI model to the DP accelerator 105. Inoperation 650, the DP accelerator can receive the AI model from the hostdevice 104.

In operation 610, the application on the host device 104 can transmitinput to the DP accelerator that is used to trigger output from the AImodel. In operation 655, DP accelerator 105 can receive the input datafrom the host device 104.

In operation 660, DP accelerator 105 can run the AI model with thereceived input data to produce an output data. The output data can be awatermark of the AI model.

In operation 675, DP accelerator can call security unit 275 of DPaccelerator 105 to digitally sign the output data (watermark). In anembodiment, digitally signing the watermark can include generating ahash or digest of the watermark, including the hash or digest in apacket with the watermark, and encrypting the packet with a private keyof the DP accelerator.

In operation 680, the DP accelerator can make the digitally signedoutput data available to the host device 104 for retrieval. In operation620, host device 104 can retrieve and, optionally, validate the outputfrom the DP accelerator running the AI model with the input data, orotherwise obtaining the watermark from a pre-existing source. Tovalidate the received, digitally signed output data, the host device candecrypt the received output using a public key of the DP accelerator 105and extract the watermark and a hash or digest of the watermark. Hostdevice 104 can compare the extracted watermark with the watermarkobtained by the host device running the AI model with the input data. Ifthey match, then host device 104 can also compute the hash or digest ofthe watermark and compare the computed hash or digest with the extractedhash or digest. If the hashes/digests match, then the DP accelerator 105successfully extracted, and digitally signed, the watermark from the AImodel using the input data.

In operation 625, host device 104 can request additional data processingoperations from DP accelerator 105 using the AI model. In an embodiment,if the watermark was not validated, host 104 can opt to not make futurecalls for to DP accelerator 105 using method 600.

FIG. 7 is a block diagram illustrating a method 700 of signing outputusing a host-provided signature kernel, according to an embodiment. Inpreparation for method 700, host device 104 and DP accelerator 105 canexchange one or more designated keys and establish a securecommunication channel 215. Embodiments according to method 700 can use,as a DP accelerator 105, an accelerator such as Baidu® AI accelerator orother AI accelerator, or an accelerator such as a GPU.

in operation 705, an application on host device 104 can send a signaturekernel to DP accelerator 105 over communication channel 215. Inoperation 750, DP accelerator 105 can receive the signature kernel fromhost device 150. The signature kernel specifies input data to access.The input data can be an AI model having a watermark. The signaturekernel can generate output data, using the input.

In operation 755, DP accelerator runs the kernel to extract a watermarkfrom the input data. The input data can be watermark-enabled AI model ordata representing a watermark of an AI model. The signature kernel canaccess the specified input data from several difference sources. Thesource of the specified input data can be specified within the signaturekernel, specified in a separate transmission from the host device 104 tothe DP accelerator 105, or can be specified by reference, such as apointer, or specified by reference to a register within the DPaccelerator, e.g. “extract the watermark from the input data or dataobject specified in the DP accelerator register AX.” The signaturekernel can generate a hash, or digest, of the watermark using any knownhash or digest technique.

In operation 756, the kernel generates output, using the input data,obtained as described above, in operation 757, the signature kernel canembed the hash or digest into the output data generated by the signaturekernel. In operation 758, the kernel can digitally sign the output data.The signature can be generated using a key previously exchanged betweenthe host device 104 and DP accelerator 105, or a private key of the DPaccelerator 105.

In operation 760, DP accelerator 105 can notify host device 104 that thedigitally signed output data is ready to be retrieved by host device104. In operation 710, host device 104 can retrieve the output data fromDP accelerator 105.

In operation 715, host device 104 can optionally validate the outputdata retrieved from DP accelerator 105. In an embodiment, validating theoutput can include an application on host device 104 performingoperations 755 through 757, then decrypting the digital signature of thedigitally signed output received from the DP accelerator, or otherwiseobtaining the specified output from a pre-existing source, and comparingthe result with the unsigned (after decrypting the signature) resultgenerated by the DP accelerator. If the two match, then the DPaccelerator 105 signature has been validated. In operation 720, host 104can make one or more additional calls to the DP accelerator andsignature kernel for additional operations. In an embodiment, if thesigned output is not validated, then host 104 can opt to not makeadditional calls to DP accelerator 105 using method 700.

FIG. 8 is block diagram illustrating a method 800 of a DP acceleratordigitally signing a watermark of an AI model using a watermark-enabledkernel and a signature kernel provided by a host device 104, accordingto an embodiment. In an embodiment, the watermark-enabled kernel andsignature kernel can be integrated into a single kernel. Method 800provides a generic AI watermark signature method to prove that an AImodel having the watermark was used by DP accelerator 105. Inpreparation for method 800, host device 104 and DP accelerator 105 canexchange one or more designated keys and establish a communicationchannel 215 between the host device 104 and DP accelerator 105. In anembodiment, DP accelerator 105 can be an accelerator such as Baidu® AIaccelerator or other AI accelerator, or an accelerator such as agraphics processing unit (GPU).

In operation 805, an application on host device 104 transmits awatermark-enabled AI model to DP accelerator 105 over communicationchannel 215. In operation 850, DP accelerator 105 receives thewatermark-enabled AI model from host device 104. In operation 810, theapplication on host device 104 transmits a watermark-enabled kernel anda signature kernel to DP accelerator 105 over communication channel 215.In operation 855, DP accelerator 105 receives the watermark-enabledkernel and signature kernel from host device 104. In an embodiment,watermark-enabled kernel and signature kernel can be a single kernelcombining the functionalities of each kernel.

In operation 815, the application on host device 104 transmits inputdata to the DP accelerator 105 over communication channel 215. The inputdata, when used as input to the watermark-enabled kernel, triggers thewatermark-enabled kernel to output a watermark of the watermark-enabledAI model. In operation 860, DP accelerator 105 receives the input datafrom the host device 104.

In operation 865, the DP accelerator runs the watermark-enabled kernel,using the received input data as input, to extract the watermark fromthe watermark-enabled AI model received from the host device 104. Inoperation 870, in an embodiment, the watermark-enabled kernel canoptionally call the signature kernel to digitally sign the watermark. Inan embodiment, the digital signature includes a hash or digest of thewatermark. In an embodiment, digitally signing the watermark includesthe hash or digest of the watermark, and encrypting the watermark andhash/digest using a private key of the DP accelerator 105.

In operation 875, DP accelerator 105 notifies the host device 104 thatthe watermark (optionally digitally signed) is available for the hostdevice 104 to retrieve. In operation 820, the application on host device104 retrieves the (optionally digitally signed) watermark of the AImodel from DP accelerator 105.

In operation 825, the host device 104 optionally validates the (e.g.,optionally digitally signed) watermark. If the watermark was digitallysigned by the signature kernel in operation 870, then the host devicecan decrypt the digital signature using a public key of the DPaccelerator 105. The hash or digest of the watermark can be unpackagedfrom the decrypted output data. Host device 104 can run thewatermark-enabled kernel to obtain the watermark from thewatermark-enabled AI model, or otherwise obtain the watermark from apre-existing source, and the host device 104 can compute the digest orhash of the watermark. If the host-computed or obtained watermark andhash match the DP accelerator-computed watermark and hash, then the DPaccelerator, watermark-enabled kernel, and signature kernel outputs arevalidated.

In operation 830, host device 104 can call DP accelerator 105 to performone or more such operations using the signature kernel andwatermark-enabled kernel. In an embodiment, if the DPaccelerator-produced watermark and digital signature are not validatedthen host device 104 can opt to not call DP accelerator 105 for furtheroperations using the watermark enabled kernel and/or signature kernel.

FIG. 9 is a block diagram illustrating an example of a data processingsystem 1500 which may be used with one embodiment of the disclosure. Forexample, system 1500 may represent any of data processing systemsdescribed above performing any of the processes or methods describedabove, such as, for example, establishing secure communications betweena host device 104 and data processing (DP) accelerator 105; running, bythe DP accelerator, kernels of code of artificial intelligence (AI)models received from host device 104; executing applications on hostdevice 104; executing API's and drivers on host device 104; runningencryption/decryption logic, seed generators, encryption/decryption keygenerators, and the like, as described above for DP accelerator 105.System 1500 can include many different components. These components canbe implemented as integrated circuits (ICs), portions thereof, discreteelectronic devices, or other modules adapted to a circuit board such asa motherboard or add-in card of the computer system, or as componentsotherwise incorporated within a chassis of the computer system.

Note also that system 1500 is intended to show a high level view of manycomponents of the computer system. However, it is to be understood thatadditional components may be present in certain implementations andfurthermore, different arrangement of the components shown may occur inother implementations. System 1500 may represent a desktop, a laptop, atablet, a server, a mobile phone, a media player, a personal digitalassistant (PDA), a Smart watch, a personal communicator, a gamingdevice, a network router or hub, a wireless access point (AP) orrepeater, a set-top box, or a combination thereof. Further, while only asingle machine or system is illustrated, the term “machine” or “system”shall also be taken to include any collection of machines or systemsthat individually or jointly execute a set (or multiple sets) ofinstructions to perform any one or more of the methodologies discussedherein.

In one embodiment, system 1500 includes processor 1501, memory 1503, anddevices 1505-1508 connected via a bus or an interconnect 1510. Processor1501 may represent a single processor or multiple processors with asingle processor core or multiple processor cores included therein.Processor 1501 may represent one or more general-purpose processors suchas a microprocessor, a central processing unit (CPU), or the like. Moreparticularly, processor 1501 may be a complex instruction set computing(CISC) microprocessor, reduced instruction set computing (RISC)microprocessor, very long instruction word (VLIW) microprocessor, orprocessor implementing other instruction sets, or processorsimplementing a combination of instruction sets. Processor 1501 may alsobe one or more special-purpose processors such as a Baidu® AI processor,a GPU, an ASIC, a cellular or baseband processor, an FPGA, a DSP, anetwork processor, a graphics processor, a communications processor, acryptographic processor, a co-processor, an embedded processor, or anyother type of logic capable of processing instructions.

Processor 1501, which may be a low power multi-core processor socketsuch as an ultra-low voltage processor, may act as a main processingunit and central hub for communication with the various components ofthe system. Such processor can be implemented as a system on chip (SoC).Processor 1501 is configured to execute instructions for performing theoperations and steps discussed herein. System 1500 may further include agraphics interface that communicates with optional graphics subsystem1504, which may include a display controller, a graphics processor,and/or a display device.

Processor 1501 may communicate with memory 1503, which in one embodimentcan be implemented via multiple memory devices to provide for a givenamount of system memory. Memory 1503 may include one or more volatilestorage (or memory) devices such as random access memory (RAM), dynamicRAM (DRAM), synchronous DRAM (SDRAM), static RAM (SRAM), or other typesof storage devices. Memory 1503 may store information includingsequences of instructions that are executed by processor 1501, or anyother device. For example, executable code and/or data of a variety ofoperating systems, device drivers, firmware (e.g., input output basicsystem or BIOS), and/or applications can be loaded in memory 1503 andexecuted by processor 1501. An operating system can be any kind ofoperating systems, such as, for example, Robot Operating System (ROS),Windows® operating system from Microsoft®, Mac OS®/iOS® from Apple,Android® from Google®, LINUX, UNIX, or other real-time or embeddedoperating systems.

System 1500 may further include 10 devices such as devices 1505-1508,including network interface device(s) 1505, optional input device(s)1506, and other optional IO device(s) 1507. Network interface device1505 may include a wireless transceiver and/or a network interface card(NIC). The wireless transceiver may be a WiFi transceiver, an infraredtransceiver, a Bluetooth transceiver, a WiMax transceiver, a wirelesscellular telephony transceiver, a satellite transceiver (e.g., a globalpositioning system (GPS) transceiver), or other radio frequency (RF)transceivers, or a combination thereof. The NIC may be an Ethernet card.

Input device(s) 1506 may include a mouse, a touch pad, a touch sensitivescreen (which may be integrated with display device 1504), a pointerdevice such as a stylus, and/or a keyboard (e.g., physical keyboard or avirtual keyboard displayed as part of a touch sensitive screen). Forexample, input device 1506 may include a touch screen controller coupledto a touch screen. The touch screen and touch screen controller can, forexample, detect contact and movement or break thereof using any of aplurality of touch sensitivity technologies, including but not limitedto capacitive, resistive, infrared, and surface acoustic wavetechnologies, as well as other proximity sensor arrays or other elementsfor determining one or more points of contact with the touch screen.

IO devices 1507 may include an audio device. An audio device may includea speaker and/or a microphone to facilitate voice-enabled functions,such as voice recognition, voice replication, digital recording, and/ortelephony functions. Other IO devices 1507 may further include universalserial bus (USB) port(s), parallel port(s), serial port(s), a printer, anetwork interface, a bus bridge (e.g., a PCI-PCI bridge), sensor(s)(e.g., a motion sensor such as an accelerometer, gyroscope, amagnetometer, a light sensor, compass, a proximity sensor, etc.), or acombination thereof. Devices 1507 may further include an imagingprocessing subsystem (e.g., a camera), which may include an opticalsensor, such as a charged coupled device (CCD) or a complementarymetal-oxide semiconductor (CMOS) optical sensor, utilized to facilitatecamera functions, such as recording photographs and video clips. Certainsensors may be coupled to interconnect 1510 via a sensor hub (notshown), while other devices such as a keyboard or thermal sensor may becontrolled by an embedded controller (not shown), dependent upon thespecific configuration or design of system 1500.

To provide for persistent storage of information such as data,applications, one or more operating systems and so forth, a mass storage(not shown) may also couple to processor 1501. In various embodiments,to enable a thinner and lighter system design as well as to improvesystem responsiveness, this mass storage may be implemented via a solidstate device (SSD). However, in other embodiments, the mass storage mayprimarily be implemented using a hard disk drive (HDD) with a smalleramount of SSD storage to act as a SSD cache to enable non-volatilestorage of context state and other such information during power downevents so that a fast power up can occur on re-initiation of systemactivities. Also a flash device may be coupled to processor 1501, e.g.,via a serial peripheral interface (SPI). This flash device may providefor non-volatile storage of system software, including BIOS as well asother firmware of the system.

Storage device 1508 may include computer-accessible storage medium 1509(also known as a machine-readable storage medium or a computer-readablemedium) on which is stored one or more sets of instructions or software(e.g., module, unit, and/or logic 1528) embodying any one or more of themethodologies or functions described herein. Processingmodule/unit/logic 1528 may represent any of the components describedabove, such as, for example, user applications 205, runtime libraries206, drivers 209 of host device 104, true random number generator 273,key manager 272, watermark unit 276, cryptographic engine 274 on DPaccelerator 105. Processing module/unit/logic 1528 may also reside,completely or at least partially, within memory 1503 and/or withinprocessor 1501 during execution thereof by data processing system 1500,memory 1503 and processor 1501 also constituting machine-accessiblestorage media. Processing module/unit/logic 1528 may further betransmitted or received over a network via network interface device1505.

Computer-readable storage medium 1509 may also be used to store some ofthe software functionalities described above persistently. Whilecomputer-readable storage medium 1509 is shown in an exemplaryembodiment to be a single medium, the term “computer-readable storagemedium” should be taken to include a single medium or multiple media(e.g., a centralized or distributed database, and/or associated cachesand servers) that store the one or more sets of instructions. The term“computer-readable storage medium” shall also be taken to include anymedium that is capable of storing or encoding a set of instructions forexecution by the machine and that cause the machine to perform any oneor more of the methodologies of the present disclosure. The term“computer-readable storage medium” shall accordingly be taken toinclude, but not be limited to, solid-state memories, and optical andmagnetic media, or any other non-transitory machine-readable medium.

Processing module/unit/logic 1528, components and other featuresdescribed herein can be implemented as discrete hardware components orintegrated in the functionality of hardware components such as ASICS,FPGAs, DSPs or similar devices. In addition, processingmodule/unit/logic 1528 can be implemented as firmware or functionalcircuitry within hardware devices. Further, processing module/unit/logic1528 can be implemented in any combination hardware devices and softwarecomponents.

Note that while system 1500 is illustrated with various components of adata processing system, it is not intended to represent any particulararchitecture or manner of interconnecting the components; as suchdetails are not germane to embodiments of the present disclosure. Itwill also be appreciated that network computers, handheld computers,mobile phones, servers, and/or other data processing systems which havefewer components or perhaps more components may also be used withembodiments of the disclosure.

Some portions of the preceding detailed descriptions have been presentedin terms of algorithms and symbolic representations of operations ondata bits within a computer memory. These algorithmic descriptions andrepresentations are the ways used by those skilled in the dataprocessing arts to most effectively convey the substance of their workto others skilled in the art. An algorithm is here, and generally,conceived to be a self-consistent sequence of operations leading to adesired result. The operations are those requiring physicalmanipulations of physical quantities.

It should be borne in mind, however, that all of these and similar termsare to be associated with the appropriate physical quantities and aremerely convenient labels applied to these quantities. Unlessspecifically stated otherwise as apparent from the above discussion, itis appreciated that throughout the description, discussions utilizingterms such as those set forth in the claims below, refer to the actionand processes of a computer system, or similar electronic computingdevice, that manipulates and transforms data represented as physical(electronic) quantities within the computer system's registers andmemories into other data similarly represented as physical quantitieswithin the computer system memories or registers or other suchinformation storage, transmission or display devices.

Embodiments of the disclosure also relate to an apparatus for performingthe operations herein. Such a computer program is stored in anon-transitory computer readable medium. A machine-readable mediumincludes any mechanism for storing information in a form readable by amachine (e.g., a computer). For example, a machine-readable (e.g.,computer-readable) medium includes a machine (e.g., a computer) readablestorage medium (e.g., read only memory (“ROM”), random access memory(“RAM”), magnetic disk storage media, optical storage media, flashmemory devices).

The processes or methods depicted in the preceding figures may beperformed by processing logic that comprises hardware (e.g. circuitry,dedicated logic, etc.), software (e.g., embodied on a non-transitorycomputer readable medium), or a combination of both. Although theprocesses or methods are described above in terms of some sequentialoperations, it should be appreciated that some of the operationsdescribed may be performed in a different order. Moreover, someoperations may be performed in parallel rather than sequentially.

Embodiments of the present disclosure are not described with referenceto any particular programming language. It will be appreciated that avariety of programming languages may be used to implement the teachingsof embodiments of the disclosure as described herein.

In the foregoing specification, embodiments of the disclosure have beendescribed with reference to specific exemplary embodiments thereof. Itwill be evident that various modifications may be made thereto withoutdeparting from the broader spirit and scope of the disclosure as setforth in the following claims. The specification and drawings are,accordingly, to be regarded in an illustrative sense rather than arestrictive sense.

What is claimed is:
 1. A computer implemented method performed by a dataprocessing (DP) accelerator, the method comprising: receiving, by the DPaccelerator, from a host device, an artificial intelligence (AI) model,a watermark-enabled kernel, and first input data, wherein thewatermark-enabled kernel comprises executable code to extract awatermark from the AI model; executing, within the DP accelerator, thewatermark-enabled kernel based on the first input data to extract thewatermark from the AI model; digitally signing the watermark using asignature key; and transmitting the watermark to the host device.
 2. Themethod of claim 1, further comprising: receiving a signature kernel fromthe host device; and invoking the signature kernel to digitally sign thewatermark using the signature key.
 3. The method of claim 1, wherein thewatermark-enabled kernel further comprises a signature kernel, andwherein the watermark-enabled kernel invokes the signature kernel todigitally sign the watermark using the signature key.
 4. The method ofclaim 1, further comprising invoking a digital signature routine in asecure unit of the DP accelerator to digitally sign the watermark byencrypting a hash of the watermark using the signature key.
 5. Themethod of claim 2, wherein the signature key is retrieved from, or thesignature key is based upon a key retrieved from, a secure storage of asecurity unit of the DP accelerator.
 6. The method of claim 1, furthercomprising exchanging one or more keys between the host device and DPaccelerator.
 7. The method of claim 6, further comprising establishing asecure link between the host device and the DP accelerator using atleast one of the one or more keys.
 8. The method of claim 6, wherein theone or more keys comprise the signature key.
 9. A data processing (DP)accelerator, comprising: a memory coupled to an interface to receivefrom a host device an artificial intelligence (AI) model, awatermark-enabled kernel, and first input data, wherein thewatermark-enabled kernel comprises executable code to extract awatermark from the AI model; and an AI unit coupled to the interface toexecute on a hardware processor within the DP accelerator thewatermark-enabled kernel based on the first input data to extract thewatermark from the AI model, digitally sign the watermark using asignature key, and transmit the watermark to the host device.
 10. The DPaccelerator of claim 9, further comprising a security unit configuredto: receive a signature kernel from the host device, and invoke thesignature kernel to digitally sign the watermark using the signaturekey.
 11. The DP accelerator of claim 9, wherein the watermark-enabledkernel further comprises a signature kernel, and wherein thewatermark-enabled kernel invokes the signature kernel to digitally signthe watermark using the signature key.
 12. The DP accelerator of claim9, further comprising a security unit configured to invoke a digitalsignature routine in a secure unit of the DP accelerator to digitallysign the watermark by encrypting a hash of the watermark using thesignature key.
 13. The DP accelerator of claim 10, wherein the signaturekey is retrieved from, or the signature key is based upon a keyretrieved from, a secure storage of a security unit of the DPaccelerator.
 14. The DP accelerator of claim 9, further comprising achannel manager to exchange one or more keys between the host device andDP accelerator.
 15. The DP accelerator of claim 14, wherein the channelmanager is to establish a secure link between the host device and the DPaccelerator using at least one of the one or more keys.
 16. The DPaccelerator of claim 14, wherein the one or more keys comprise thesignature key.
 17. A non-transitory machine-readable medium havinginstructions stored therein, which when executed by a processor, causethe processor to perform operations of a data processing (DP)accelerator, the operations comprising: receiving, by the DPaccelerator, from a host device, an artificial intelligence (AI) model,a watermark-enabled kernel, and first input data, wherein thewatermark-enabled kernel comprises executable code to extract awatermark from the AI model; executing, within the DP accelerator, thewatermark-enabled kernel based on the first input data to extract thewatermark from the AI model; digitally signing the watermark using asignature key; and transmitting the watermark to the host device. 18.The machine-readable medium of claim 17, wherein the operations furthercomprise: receiving a signature kernel from the host device; andinvoking the signature kernel to digitally sign the watermark using thesignature key.
 19. A host device, comprising: a processor; and a memorycoupled to the processor to store instructions, which when executed bythe processor, cause the processor to perform operations, the operationscomprising: transmitting, by the host device, to a data processing (DP)accelerator, an artificial intelligence (AI) model and awatermark-enabled kernel, wherein the watermark-enabled kernel comprisesexecutable code to extract a watermark from the AI model, transmitting,by the host device, first input data to the DP accelerator as input tothe watermark-enabled kernel, and receiving the watermark extracted fromthe AI model from the DP accelerator, wherein the DP accelerator isconfigured to execute the watermark-enabled kernel based on the firstinput data to extract the watermark from the AI model and to digitallysign the watermark using a signature key.
 20. The host device of claim19, wherein the operations further comprise transmitting, by the hostdevice to the DP accelerator, a signature kernel that, when called bythe watermark-enabled kernel, digitally signs the watermark byencrypting a hash of the watermark using the signature key before the DPaccelerator returns the watermark to the host device.